Mammography information system

ABSTRACT

A method and system for analyzing and retrieving breast tissue abnormality tracking data, providing a tool for a radiologist that includes a report summarizing the statistical frequency of diagnosed patients, both locally and nationally, with breast tissue region-of-interest classifications similar to the breast tissue images taken of the anatomy of an individual patient. A computer aided diagnostic program can be tested or verified against the breast tissue images and the region-of-interest classifications that have been validated by definitive patient diagnosis. Methods and systems allow the efficient collection of all of the breast tissue abnormalities for a given medical facility in order to provide trending data or radiologist performance analysis. The region-of-interest abnormalities in a single location in a patient&#39;s tissue are correlated across a variety of imaging modalities including X-rays, mammogram, CT, ultrasound, MRI, or other imaging technologies.

RELATED APPLICATIONS

This application is a continuation of application Ser. No. 12/625,898 filed Nov. 25, 2009, which claims the benefit of U.S. Provisional Application No. 61/282,000 filed Nov. 24, 2009, which is hereby fully incorporated herein by reference.

The following co-pending patent applications of common assignee contain some common disclosure: “Multiple Modality Mammography Image Gallery and Clipping System,” Attorney Docket No. 3080.20US01 and “Mammography Statistical Diagnostic Profiler and Prediction System,” Attorney Docket No. 3080.21US01, filed Nov. 25, 2009, having Ser. No. 12/625,926 (now U.S. Pat. No. 9,171,130) and Ser. No. 12/625,910 (now U.S. Pat. No. 8,687,860), respectively, which are incorporated herein by reference in their entireties.

TECHNICAL FIELD

The invention relates to management of medical data and more specifically to patient data and breast tissue images originating from multiple modalities.

BACKGROUND

Historically, interpretation and diagnosis of mammograms and other medical image analysis has been performed using hardcopy x-ray films viewed on an alternator that typically allows x-ray films to be illuminated and masked for diagnostic viewing. Newer technology allows a radiologist or other medical professional to view mammograms and other diagnostic images electronically on high-resolution monitors. These images can also be digitally stored and transmitted across secure networks for archiving or review by other professionals.

A radiologist generally begins his or her review process by reviewing a patient's background information relevant to a radiology study, such as a patient's name, age, and any applicable medical conditions or risk factors. After reviewing the background information, the radiologist views multiple images created by radiological, X-ray, computed tomography (CT), ultrasound, magnetic resonance imaging (MRI), tomosynthesis, or other imaging technique of the patient's breast, or other organ, and dictates or uses a computerized information system to track findings, create reports, and make recommendations for future examinations. Such findings can include information pertaining to tissue density, the presence of masses, cysts, calcifications and other abnormalities, or any other breast tissue characteristics.

While there has been recent debate regarding the frequency at which women should undergo regular mammogram screenings, and at what age such screenings should begin, it is unlikely that the relatively quick and typically effective practice of mammography screening for breast cancer will disappear completely. Accordingly, there will continue to be a need for radiologists to view and interpret the images generated from patient examinations and screenings. Because the risk of breast cancer threatens the lives of many women, especially those over age 40, radiologists are often inundated with large numbers of mammogram images that must be viewed and, if abnormalities are present, categorized in order to determine if further examination is required. The developments in advanced patient imaging techniques, such as MRI, are also increasing the raw number of images that a radiologist can review. Therefore, there is an ongoing need to improve the speed and efficiency of the radiologist's review of the mammogram images, without sacrificing accuracy, and with the smallest number of false-positive diagnoses. Additionally, given that mammogram screenings are performed periodically, such as annually or biannually, once screening begins for a particular woman, there is also a need to manage, track and analyze data taken over a period of years or decades for that woman.

One example of a computerized mammography information system (MIS) to review patient images is the PenRad Mammography Information System available from PenRad. This system provides for the digital presentation of patient data.

Legislation has mandated that mammography facilities track positive mammography findings and correlate such findings with biopsy results, maintain statistics for mammography medical outcome and analysis audits on each physician, and provide direct written notification to all patients of their exam results. The generation and correlation of this data is maintained locally by each medical center for each patient.

One system for categorizing this information is the Breast Imaging-Reporting and Data System (BI-RADS) published by the American College of Radiology (ACR). BI-RADS provides a system of mammography assessment categories in the form of standardized codes assigned by a radiologist during or after the viewing and interpretation of a medical image. BI-RADS allows for concise and unambiguous understanding of patient records between multiple radiologists and medical facilities. Consequently, a large number of mammogram images, biopsy results, and diagnosis statistics are potentially available in a patient-anonymous format, in compliance with the Health Insurance Portability and Accountability Act of 1996 (HIPAA).

Recently, Digital Imaging and Communications in Medicine (DICOM) systems have become the accepted format for medical imaging systems. This format provides for the distribution and viewing of medical studies and images across a variety of platforms. The use of DICOM has, among other things, enabled industry compatibility and improved workflow efficiency between imaging and other information systems located in various healthcare environments. Currently, the DICOM standard is an 18-part publication, PS 3.1-2008 through PS 3.18-2008 describing a standard for digital imaging and communications in medicine developed by the American College of Radiology (ACR) and the National Electrical Manufacturers Association (NEMA), which is hereby incorporated by reference in its entirety. Among other elements, the DICOM standard provides a method of uniquely numbering any image or other information object to facilitate the unambiguous identification of images or information objects as they are viewed or manipulated in a system or transported across a network.

Conventional imaging systems enable a DICOM server to provide medical images across a network to various DICOM compatible clients on the network. Some examples of DICOM clients include picture archiving and communications systems, softcopy workstations, computer-aided diagnosis (CAD) systems, DICOM compatible CD or DVD burners, and other network system devices known to those skilled in the art. One example of a standards-based medical imaging environment is disclosed in U.S. Pat. No. 6,909,795, to Tecotzky et al., incorporated herein by reference.

SUMMARY OF THE INVENTION

Embodiments of the invention relate to systems and methods of retrieving and analyzing patient data in a mammography information system as part of or in conjunction with the diagnosis and interpretation of patient mammography images that substantially meet the aforementioned needs of the industry. In an example embodiment, the system is capable of retrieving, presenting, and analyzing patent images originating from a variety of modalities.

In an embodiment, a configurable mammography diagnostic system comprises a plurality of electronic displays, at least one of the plurality of electronic displays configured to display a breast tissue image having at least one region of interest, a database including a plurality of existing categorizations of at least one known region of interest in at least one of a plurality of breast tissue images, a graphical user interface presented on at least one of the plurality of electronic displays and including an anatomical diagram on which the at least one region of interest can be marked, a detailing button linked to a screen configured to present a plurality of possible characteristics according to which a manual current categorization of a region of interest in the breast tissue image can be defined, and a profiler display button configured to present statistical information related to a comparison of the manual current categorization with the existing categorizations, a clipping tool with which a portion of the breast tissue image displayed on at least one of the plurality of electronic displays can be selected as a second image, the second image displayable on at least one of the plurality of electronic displays as a subset of the breast tissue image, and a processing engine configured to link the second image to the breast tissue image, store the second image in an image database, and to associate the second image with a corresponding region of interest marked on the anatomical diagram.

In an embodiment, a method for managing patient mammography data comprises obtaining a plurality of breast tissue images selected from the group consisting of an X-ray image, a CT image, an MRI image, an ultrasound image, and a pathology image, identifying a region of interest in at least one of the plurality of breast tissue images, obtaining a categorization of the region of interest according to an established lexicon, comparing the categorization with a database of existing categorizations and presenting a diagnostic indicator based on the comparing, storing a selected region of the at least one of the plurality of breast tissue images as a second image, mapping the second image to a storage location of the at least one of the plurality of breast tissue images, and associating the selected region with the categorized region of interest.

In an embodiment, a mammography information system comprises at least one electronic display, a graphical user interface presented on the at least one electronic display and configured to present data and information related to a patient, the graphical user interface comprising an image gallery configured to display thumbnail representations of a plurality of images that form a portion of the data and information, the plurality of images selectable from X-ray images, CT images, MRI images, ultrasound images, pathology images and document images, and a database operable to store the thumbnail representations of the plurality of images.

The above summary of the invention is not intended to describe each illustrated embodiment or every implementation of the present invention. The figures and the detailed description that follow more particularly exemplify these embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

The embodiments of the present invention may be more completely understood in consideration of the following detailed description of various embodiments in connection with the accompanying drawings, in which:

FIG. 1 is an example mammogram information system (MIS) display workstation according an embodiment of the invention.

FIG. 2 is an example of a mammography exam data-form suitable for use with embodiments of the invention.

FIG. 3 is an example of the mammography exam data-form of FIG. 2 indicating a region of interest (ROI).

FIG. 4 is an example of a mammogram image with an ROI indicated.

FIG. 5 is an example of an ultrasound image with an ROI indicated.

FIG. 6 a is another example embodiment of a ROI data entry form for use with embodiments of the invention.

FIG. 6 b is the ROI data entry form of FIG. 6 a with additional ROI categorizations entered.

FIG. 6 c depicts two additional exemplary embodiments of ROI data entry forms for use with embodiments of the invention.

FIG. 7 is an example of a form showing the statistical analysis of a ROI.

FIG. 8 is an example of a form showing available images that match statistical analysis of the ROI of FIG. 7.

FIG. 9 is an example of a form showing a patient's exam history.

FIG. 10 is an example embodiment of a report generated according an embodiment of the invention.

FIG. 11 is an example embodiment of a web-based form for use with an embodiment of the invention.

FIG. 12 is an example embodiment of a web-based form for use with an embodiment of the invention.

FIG. 13 is an example embodiment of a web-based form for use with an embodiment of the invention.

FIG. 14 is an example embodiment of a web-based form for use with an embodiment of the invention.

FIG. 15 is an example of a mammography exam data-form and an example of a ROI gallery window.

FIG. 16 a is an another depiction of the ROI gallery window of FIG. 15.

FIG. 16 b is another example of a ROI gallery window for use with embodiments of this invention.

FIG. 17 is an example embodiment of a ROI viewer depicting an individual image for use with embodiments of this invention.

FIG. 18 is an example of an interpretation work-list form for use with embodiments of the invention.

FIG. 19 is an example of a prior examinations form for use with embodiments of this invention.

While the present invention is amenable to various modifications and alternative forms, specifics thereof have been shown by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not to limit the present invention to the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the present invention as defined by the appended claims.

DETAILED DESCRIPTION OF THE DRAWINGS

Embodiments provide a computerized mammography information system that allows for the digital correlation of a wide variety patent data related to a mammography image or other breast tissue diagnostic imaging procedures. An exemplary system is able to electronically track breast tissue abnormalities across multiple image types, provide a customizable interface for convenient and efficient image review, allow for an individual user to save preferred image hanging protocols, categorize multiple imaging types, generate statistics, and provide patient correspondence. Additionally, the integration of various computer aided diagnostic/detection (CAD) protocols for multiple image modalities into the system assists the medical professional in reviewing and accurately diagnosing any abnormalities present in a patient's diagnostic images. This advancement in accuracy also provides the benefit of reducing the need for expensive and invasive biopsy or surgery due to false positive diagnosis.

Embodiments of the mammography information system provide an efficient, easy to use, and customizable interface for use by a medical professional for the review and analysis of medical images from a variety of source. The system is capable of integrating medical images acquired through X-ray, CT, ultrasound, MRI, tomosynthesis, or other imaging techniques.

The increasing availability and quantity of digital information representing patient medical data and diagnostic images has created a need for a system that allows a doctor or radiologist to quickly review, organize, and if necessary retrieve, multiple diagnostic images that may be indicative of an individual patient's condition. In addition to the availability of digital mammography images, other patient associated data, such as biopsy or other test results and even entire medical histories or correspondence records can be stored in a digital format. Access to images where the pictured abnormality has been definitively diagnosed can assist with the doctor or radiologist's diagnosis of the new patient's individual condition. Prior to the electronic production, archival, and detailed categorization of patient images, such comparisons were limited to a handful of common abnormalities described in the various medical texts or required laborious manual review of individual patient files.

Therefore, there is a need for a system that will quickly allow a radiologist to select a ROI in a mammogram or other image and correlate the ROI to a mapping or outline of the patient's anatomy in order to improve efficiency of patient diagnosis and record retrieval including a mechanism to “clip” a ROI from any image modality, or form of electronic record, and associating that “clipping” with a specific ROI placement in the patient's record.

Additionally, the availability of this collection of breast tissue images and their associated biopsy results presents an opportunity for statistical analysis of the likelihood that a matching region of interest (ROI) in an individual patient's mammography images is malignant or benign and whether or not a biopsy or further imaging should be ordered. Therefore, there is a need for a system that will quickly allow a radiologist to classify a ROI in a mammogram or other image and correlate the ROI to a large pool of existing data samples that have been definitively diagnosed in order to improve the accuracy and efficiency of patient diagnosis. The radiologist can be assisted in the classification of the ROI by a CAD module by automatically detecting potential ROI abnormalities or simply reducing the number of physical or verbal actions needed by the radiologist to enter the ROI classifying data.

In an example embodiment, a MIS is provided for use by a radiologist or other medical professional that preloads all of an individual patient's medical images for a specific portion of the patient's anatomy, regardless of the modality used to create the images. For example, in a breast cancer screening, any available x-ray, ultrasound, MRI, biopsy, or other images for the patient are retrieved and preprocessed by an appropriate CAD algorithm. A CAD module for the appropriate image type can isolate one or more ROI for review in an individual image. The disclosed invention takes these individual CAD results and correlates any common ROI findings between images of the same or different modalities. A summary “map” or outline of the examined patient's anatomy is then generated and displayed for the medical professional along with any other details about the potential ROI(s) that were generated by the CAD module(s).

The mammography image gallery and clipping system according to the present invention provides a convenient organization of all of the images associated with a ROI, regardless of modality, for presentation to a medical professional. The system stores lower resolution clippings, or thumbnail images, for pathological images, reports, and abnormalities found, and optionally categorized, by radiologists or CAD products at a facility that have been entered into a mammography information system. The system stores low resolution images as well as the reference to the original image and ROI of the original image. As more patients are definitively diagnosed and their pathology records updated in the system, the larger the collection of abnormality images depicting a previously diagnosed and imaged condition that become available in the system. This system can be integrated into an existing MIS or utilized as a standalone interface providing access to a large sample of mammogram abnormality images.

The system also provides an efficient mechanism for creating a comprehensive collection of abnormality data. The collection comprising a uniform lexicon of classifications that allows for further analysis and study of the data while still maintaining patient privacy as required by the applicable law. Those skilled in the art of developing and maintaining electronic databases will appreciate and understand the tradeoffs associated with the storage requirements necessary for the implementation of the contemplated system. As numerous mammography facilities implement this non-patient identifying (and HIPAA compliant) data can be transferred to a central location accumulating a more complete database of abnormality images and the corresponding characterization of data points for various pathology types.

In an example embodiment, the method of analyzing and retrieving abnormality tracking data provides a report of the statistical frequency of diagnosed patients both locally and nationally with mammogram ROI classifications similar to an individual patient. The abnormality data can include information disclosing the frequency of similar ROI classifications have been biopsied and the number of biopsies that were malignant or benign. The disclosed method of capturing and reporting abnormality tracking data provides a radiologist or other medical professional a tool to assess the likelihood of a ROI being malignant or benign, and whether or not the patient should undergo additional testing. The system then presents these statistics to the radiologist who can then choose to look further into the underlying related data if he or she desires.

The statistical mammography predictive system according to the present invention provides instantly and continually updated outcome statistics to a medical professional. The system utilizes the information and data points for each and every abnormality found by radiologists at a facility that have been entered into a mammography information system. As more patients are definitively diagnosed and their pathology records updated in the system, the greater the chances that an individual patient will have a condition similar to a previously diagnosed and imaged condition. This system can be integrated into an existing MIS or utilized as a standalone interface providing access to a large sample of mammogram abnormality data.

The system also provides an efficient mechanism for creating a comprehensive collection of abnormality data. The collection comprising a uniform lexicon of classifications that allows for further analysis and study of the data while still maintaining patient privacy as required by the applicable law. Only unique copies of each combination of tracing data points must be kept in the system. As duplicate data is accumulated the counters of the abnormality and its diagnosis as benign or malignant are incremented. This aggregation of data creates a compact and anonymous abnormality database for the medical location. If desired, a complete reference of all abnormality data can be maintained. Those skilled in the art of developing and maintaining electronic databases will appreciate and understand the tradeoffs associated with the storage requirements necessary for the implementation of the contemplated system.

As numerous mammography facilities implement this non-patient identifying (and HIPAA compliant) data can be transferred to a central location accumulating an more complete database of abnormalities and the corresponding benign or malignant counters for each combination of tracking points and pathology. Therefore, the large number of recorded abnormalities can be culled down to a manageable set of unique combinations specified by radiologists around the country. This culling, or grouping of duplicate abnormalities, allows for a medical professional to access a comprehensive database of the known set of abnormalities nearly instantaneously.

In a further embodiment, the system disclosed provides a mechanism to evaluate, validate, and improve any of a variety of existing CAD modules and techniques by providing an efficient platform for testing the cad module or technique against a wide variety of known, physician evaluated, and definitively diagnosed, patient abnormalities or ROI.

The invention can be better understood by reference to FIGS. 1-19. FIG. 1 illustrates an example embodiment of a mammogram display workstation 100. A typical mammogram display workstation 100 includes a controller display system 110 and at least one high-resolution image monitor 112. One or more additional high-resolution image monitor units 114 can also be used to provide additional viewing area to provide for the comparison of two or more images at full resolution. The controller display system 110 is any of a variety of commonly available video display monitors coupled to a personal computer such as an IBM-PC or compatible system running a version of the Microsoft WINDOWS operating system, or the equivalent thereof. In an embodiment, the image monitors 112 and 114 are liquid crystal displays (LCDs) that provide high-resolution and enhanced contrast for ease of viewing images, but may also be a cathode ray tube or other appropriate display in other embodiments. An exemplary image monitor can display approximately 2500×2000 pixels, although a variety of image monitor sizes are contemplated. In one embodiment, the mammogram display workstation 100 includes a server computer (not shown) that runs DICOM communications components of the mammogram display workstation 100; alternatively, this DICOM software may run on the controller display system 110. In yet another embodiment, a server computer is included that runs an Archived Image Retrieval service; alternatively, this software may also run on the controller display system 110 or on the DICOM compliant server.

The mammogram display workstation 100 includes software that allows images to be analyzed using the image processor in the controller display system 110 to analyze each image of a study set, compare with complementary images to generate a suspect list to reduce false indicators, and to generate graphic overlay images to identify areas of interest. When an image is displayed on an image monitor 112 or 114, imaging tools included in the system allow a user working with the system to further manipulate an image. These software tools may provide magnification of a desired region of an image; image inversion, reversal, rotation, or other repositioning; image/background color inversion; noise filtering from images to reduce or eliminate extraneous data and enhance pertinent image data; customized side-by-side image comparisons; and image reorganization, for example.

FIG. 2 illustrates an example embodiment of a medical diagnostic system that includes an abnormality-summary window 200. Abnormality-summary window 200 provides a convenient patient information summary 210 and an interface to import or enter additional data. In window 200 the radiologist can enter abnormality data for either the left or right breast by clicking on an “Add Abnormality” button 220. Additionally, a user can import a CAD report detailing any abnormalities that have been detected by existing CAD software. Examples of suitable CAD software include the CadStream product by Confirma and the B-CAD product by Medipattern, among others.

As shown in FIG. 3, imported CAD information stored in compliance with a pre-determined system such as BI-RADS can be used to generate a wire-frame map or guide 230 depicting the location and depth of a ROI in or on a patient's anatomy that was detected by the CAD software or entered manually by a radiologist. The density of the patient's tissue is also presented in selector 240. The guide 230 includes both a craniocaudal (CC) view 250 and a mediolateral/oblique (ML) view 260 of both the left and right breasts of a patient. The ROI is depicted by the craniocaudal mark 252 and the mediolateral mark 262. In other situations, an abnormality may only be visible in one or the other of the ML or the CC view and, accordingly, only a single mark would be displayed in either the craniocaudal (CC) view 250 or the mediolateral/oblique (ML) view 260.

In an embodiment, the ROI data underlying either craniocaudal mark 252 or mediolateral mark 262 can be represented as the number of pixel spaces from at least two edges of the original image represented by the ROI. The retention of the number of pixels from at least two edges provides for the derivation of the location of the ROI on the original image. This allows the storage of multiple ROI for a single high-resolution image without the need to store multiple copies of the high-resolution image or even high-resolution clippings. It also permits derivation or mapping of an ROI in one image to other images based on known pixel sizes and edge distances.

In another alternative embodiment, the data underlying these two marks are used to then calculate an approximate location of the abnormality as viewed by a physician when facing the patient. This calculation also compensates for the fact that during the creation of a mammography image, the patient's breast is compressed to increase the amount of viewable tissue in the two-dimensional x-ray image. Additionally, compensation must be made for the angle at which the mediolateral/oblique view 260 is taken relative to the craniocaudal view 250 during mammogram imaging. Those skilled in the art will appreciate that the two views are not necessarily created at angles exactly perpendicular to each other due to the wide variety of patient anatomy and the need to capture as much tissue as possible in each image. The breast orientation, size and thickness information is provided along with the mammogram image. The resulting combination of the craniocaudal data and the mediolateral data produce the clock-position 270 as shown for the exemplary ROI. This calculation is not calculated if the ROI is only visible on a single image, as both a craniocaudal and mediolateral position are required, along with a distance either from the patient's nipple or chest wall, to calculate the location of the ROI in three-dimensional space.

An abnormality does not need to be located or seen in both views to be characterized. Often in mammography an abnormality is only seen in one view and additional imaging is conducted to confirm its location in another view. The additional imaging can also reveal superimposed tissue, a situation in which the breast tissue of several layers was compressed together causing a potential mass seen in a single image with the appearance of an actual abnormality. A radiologist viewing multiple images of the same tissue area can appropriately categorize these situations.

Also shown in FIG. 3 is a three-word indication 272 of the approximate location of the ROI in the patient's breast. In this example the ROI is located in the inferior (lower), lateral (outside), middle (distance between the chest and nipple) portion of the patient's right breast. Similar terms for the remaining quadrants and depth are provided by the ACR guidelines and will be understood by those skilled in the art.

An additional feature of the system is the capability of importing any ROI from a patient's previous examination that are already present in the system's database. A radiologist or technician can select the “Clone Prev” button 280 to review and import data from a previous examination. This feature further eliminates the need for duplicated effort on the part of the medical professional conducting the review of the patient's exam images.

The system is capable of handling a variety of imaging technologies. FIG. 4 depicts an exemplary x-ray generated mammogram image 300 with an ROI indicated by a dashed outline 310 on the image 300 of the patient's breast tissue 320. FIG. 5 depicts an exemplary ultrasound image 330 with an ROI indicated by a dashed outline 340 on the image 330 of the patient's breast tissue 350. While the type of information depicted in a mammogram image 300 is clearly different from the ultrasound image 330, the system maintains the ROI indicated on each respective image by storing the coordinates of each ROI as an offset, in one embodiment utilizing the number of pixels, from at least two edges of the original digital image, regardless of the technique employed to generate the image. These coordinates are then used to calculate the distance from the patient's chest wall, nipple, or other appropriate reference point, to determine the measurements defining the location of the ROI. Similar techniques can be applied to other imaging technologies such as MRI or CT images that are capable of being stored in a standardized digital format where the correlation of the number of pixels in the image to the real-world distance depicted in the image is known.

FIG. 6 a depicts an embodiment of an abnormality-detailing window 400. The detailing window 400 provides an interface for a radiologist to enter or view the detailed attributes that describe an abnormality in a selected ROI. FIG. 6 a depicts the single attribute 402 of a “Mass” as being selected to describe the ROI depicted in FIG. 3. As indicated by the system, the presence of a mass alone is generally not enough to indicate the presence of a malignancy. The radiologist then selects an impression 404 and an appropriate recommendation in the “Impression & Recs” area 406. In one embodiment, the system suggests an impression or recommendation in area 406 based on other selected attributes in window 400, which can then be reviewed by the radiologist and altered, if desired. The system can also dynamically and automatically adjust the selection in area 406 if other attributes in window 400 are changed during review. In other embodiments, area 406 is selectable by a radiologist or doctor.

The abnormality-detailing window 400 can include a profiler button 410 that provides a count of matching abnormalities and their pathological outcome. The profiler button 410, or another appropriate window, displays the number of biopsies performed that were diagnosed as malignancies 412, the number of biopsies performed that were diagnosed as benign 414, and the total number of matching abnormalities 416 in the database. The sum of the number of malignancies 412 and the number of benign 414 is the total number of biopsies performed on abnormalities possessing the same attributes selected in detailing window 400 at that location. The second line 418 of profiler window 410 displays these same quantities found in a national database. As discussed above, the single attribute of a Mass 402 in FIG. 6 a yields a relatively low number of malignancies 412 (roughly 1.4%) of similar abnormalities in the local database. The combination of the number of malignancies 412 and the number of benign 414 is also a low percentage of the total number of similar abnormalities, indicating a low frequency of requests by the patient's physician for a biopsy. The profiler button 410 is depicted in the lower corner of the screen to provide a convenient, yet out of the way area to present statistical information. Other locations or embodiments, such as a floating window that can be repositioned by the radiologist are contemplated.

Two database versions are typically present in every system—one is the “local” version containing the data specific to the medical facility where the system is installed. This local data can be subsequently uploaded to a centralized server to be integrated with into a “regional,” “national,” or “global” version of the database. This allows individual users to compare their own facility's results with a larger sample of results. Additionally, the “local” version can be linked to the on-site examination image data, allowing the radiologist to see other examinations related to a specific pathology finding or set of characteristics. The radiologist can then nearly instantly view selected examinations, images, or specified regions of interest retrieved from the local database. The system can also be configured to link to information and retrieve images from the larger databases, although in one embodiment this can be done without any patient identifying information.

FIG. 6 b depicts the abnormality-detailing window 400 of FIG. 6 a, with three additional characteristics that describe the ROI. The Mass 402 is characterized as “Irregular” 420, “Microlobulated” 422, and having a “High density” 424. In the “Impression & Recs” area 406 the addition of the “5 Highly suggestive” 426 attribute indicates that a follow-up examination of the patient is necessary. In this case, the radiologist has selected the “Ultrasound guided bx” option 428, indicating that the recommended next step for the patient is an ultrasound-guided biopsy of the abnormality.

The addition of the three ROI characteristics in FIG. 6 b significantly narrowed the number of matching abnormalities in the MIS database as shown in the profiler button 410. While only half of the biopsied abnormalities resulted in a result of malignancy 412 for the local database, as seen in the national database line 418, the vast majority of biopsied abnormalities of this type were malignant. While the relatively low number of data points presented for this abnormality type may not be sufficient to draw any definitive conclusions, this example shows the utility of being able to compare a local sample with a larger multi-site database of abnormalities providing an indication to the local medical personnel that further review of this abnormality scenario may be required. Those skilled in the medical and radiology arts will appreciate these and other advantages that this collection of data and the ease of access provided by the system yield.

FIG. 6 c depicts another example of a right breast MRI abnormality-detailing window 440 and an example of an MRI abnormality-dimensioning window 442. These two windows display the BI-RADS compatible data points, optionally generated by a CAD software package used to pre-evaluate and generate the ROI in the MIS. In one embodiment, the CAD software package can populate the various fields presented by an abnormality window, such as exemplary MRI abnormality-dimensioning window 442. These widows also provide a radiologist with an interface to adjust, re-characterize, correct, or remove the ROI data based on their professional assessment of the ROI depicted in the patient's images. As depicted, in abnormality-dimensions window 442 a radiologist can quickly select or change the radial size, anti-radial size, transverse size, AP size, cranio size, distance from the nipple, distance from the skin, and distance from the chest, of the abnormality. Other appropriate measurements or mechanisms for entering these values are also contemplated.

The system contemplated in the example embodiment dynamically updates the values shown in the profiler button 410, of FIG. 6 b, every time a new attribute is selected in abnormality-detailing window 400. One embodiment can achieve this high access speed by assigning an enhanced version of ACR lexicon descriptors to individual bits in a group of integers. This approach also yields a relatively compact database size, further minimizing search time. The tables below provide an exemplary sampling of potential abnormality lexicons. Each item in a lexicon is assigned a value. In Table 1, the STATS_VALUES field first provides a specified index into a list of database field values. These database fields are assigned indexes numbered 0 to n-1. The second hexadecimal value is the actual value assigned to the individual lexicon item. When this item is selected during an examination, the specified bit value is set in the assigned integer field using a bitwise OR operation. The LISTBOX_NAME column provides the general description of where on the abnormality-detailing window 440 the attribute would be grouped. The ITEM_NAME column provides the detailed characteristic that a radiologist can select when characterizing a patent image.

TABLE 1 Mammogram Lexicon Item Detailing LISTBOX_NAME ITEM_NAME STATS_VALUES Specify Abnormality Fibrocystic tissue 0, 0x00000001 Specify Abnormality Cyst simple 0, 0x00000002 Specify Abnormality Mastitis area 0, 0x00000004 Specify Abnormality Mass solid 0, 0x00000008 Specify Abnormality Lesion 0, 0x00000010 Specify Abnormality Cyst 0, 0x00000020 Specify Abnormality Abscess 0, 0x00000040 Specify Abnormality Mass 0, 0x00000080 Specify Abnormality Papillary lesion 0, x000000100 Profile Abnormality Irregular 1, 0x00000001 Profile Abnormality Lobulated 1, 0x00000002 Profile Abnormality Oval 1, 0x00000004 Profile Abnormality Reniform 1, 0x00000008 Profile Abnormality Round 1, 0x00000010 Profile Abnormality Circumscribed 1, 0x00000020 Profile Abnormality Microlobulated 1, 0x00000040 Profile Abnormality Obscured 1, 0x00000080 Profile Abnormality Indistinct 1, 0x00000100 Profile Abnormality Spiculated 1, 0x00000200 Profile Abnormality Intraductal 1, 0x00000400 Profile Abnormality Irregular 1, 0x00000800 Profile Abnormality Smooth 1, 0x00001000 Profile Abnormality High density 1, 0x00002000 Profile Abnormality Equal density 1, 0x00004000 Size and Distance Parallel/skin 1, 0x00800000 Size and Distance Perpendic/skin 1, 0x01000000 Assoc Calcs Generic calcs 2, 0x00000001 Assoc Calcs Amorphous 2, 0x00000002 Assoc Calcs Branching 2, 0x00000004 Assoc Calcs Coarse 2, 0x00000008 Assoc Calcs Dystrophic 2, 0x00000010 Assoc Calcs Eggshell 2, 0x00000020 Assoc Calcs Lucent-centered 2, 0x00002000 Assoc Calcs Milk of calcium 2, 0x00004000 Assoc Calcs Pleomorphic 2, 0x00008000 Assoc Calcs Punctate 2, 0x00010000 Assoc Calcs Rim 2, 0x00020000 Assoc Calcs Round 2, 0x00040000 Assoc Calcs Skin 2, 0x00080000 Assoc Calcs Spherical 2, 0x00100000 Assoc Calcs Suture 2, 0x00200000 Assoc Calcs Vascular 2, 0x00400000 Assoc Calcs Clustered 2, 0x00800000 Assoc Calcs Diffuse 2, 0x01000000 Assoc Calcs Grouped 2, 0x02000000 Assoc Calcs Linear 2, 0x04000000 Assoc Calcs Regional 2, 0x08000000 Assoc Calcs Scattered 2, 0x10000000 Assoc Calcs Segmental 2, 0x20000000 Associated findings Hematoma 3, 0x00000001 Associated findings Nipple retract 3, 0x00000002 Associated findings Seroma 3, 0x00000008 Associated findings Skin involvement 3, 0x00000010 Associated findings Skin lesion 3, 0x00000020 Associated findings Skin retraction 3, 0x00000040 Associated findings Skin thicken 3, 0x00000080 Associated findings Trab thicken 3, 0x00000100 Change From Prior Incr in size 3, 0x00000200 Change From Prior Decr in size 3, 0x00000400 Change From Prior Incr in calcs 3, 0x00002000 Change From Prior Decr in calcs 3, 0x00004000 Change From Prior Incr in number 3, 0x00008000 Change From Prior Decr in number 3, 0x00010000 Change From Prior Less prom. 3, 0x00020000 Change From Prior More prom. 3, 0x00040000 Associated findings Archit distortion 3, 0x00080000 Associated findings Axillary adenop 3, 0x00100000 Associated findings Chest wall invas 3, 0x00200000

The database of ROIs created from all examinations, detailed abnormalities, and pathology is generated and electronically stored at one or more sites. The information is then concatenated. As each exam and abnormality's result is created using the bitwise technique mentioned above, a search is made for an identical pathology finding with the identical set of bitset integer values (lexicon items) describing the abnormalities. If not found, a single record is created for each final abnormality pathology finding for each unique set of integer “lexicon” values. When duplicates are found, abnormality, benign, and malignant, the appropriate counters are incremented and the data displayed in profiler button 410 is updated.

In querying the database, the user selects lexicon items and/or pathology findings and the statistical system will instantly show “quick” statistics (total #'s only) in profiler button 410 for other exam abnormalities that “include” the profile of selected items. When the radiologist selects “round shape” he will instantly see statistics for all other abnormalities with a “round shape,” noting how many were ultimately benign, how many were malignant, and how many were never biopsied. The radiologist can also view a statistical list of findings for all abnormalities with “round shape,” perhaps helping determine probabilities for malignancy. If the radiologist subsequently also selects “spiculated margin,” the same process will occur for all abnormalities with a “round shape” AND a “speculated margin.”

An example embodiment can use a bit-setting method to produce a typical database that is small enough such that it can be loaded into the main memory of the MIS to enable rapid retrieval and updates. In an embodiment, the loading process is performed by a background thread during system startup allowing the user to continue working during loading. In querying the database, all the system needs to do is convert the currently selected lexicon items into their corresponding bitmap values, and then search the database using an “exclusive OR” (xor) comparison on the database records. A record matches when all the “set” bit values from the selected items are “set” in the database record being compared. Abnormality, Benign, and Malignant counts on each matching record are tabulated and ultimately presented to the radiologist.

The combination of the high-speed statistical comparison database and the ROI image database allows an embodiment of the system to provide a radiologist with images stored at a local facility for comparative diagnostic purposes. The system also allows a radiologist to select images based on the BI-RADS or other lexicon abnormality descriptors, allowing a comparison of additional images from a larger database or final pathology results if the abnormality was biopsied. Table 2 provides on exemplary mapping of BI-RADS values to the more efficiently stored and searched bit-field values.

TABLE 2 Mammogram Lexicon to BIRADS Conversion and Detailing DATABASE DESCRIPTOR BIT-FIELD ABNORMALITY CLASSIFICATION ID NUMBER VALUE Mass Irregular 16 0x00000001 Shape Lobulated 190 0x00000002 Oval 15 0x00000004 Reniform 27 0x00000008 Round 14 0x00000010 Margin Circumscribed 109 0x00000020 Microlobulated 111 0x00000040 Obscured 28 0x00000080 Indistinct 21 0x00000100 Spiculated 29 0x00000200 Intraductal 201 0x00000400 Irregular 20 0x00000800 Smooth 18 0x00001000 Density High density 211 0x00002000 Equal density 213 0x00004000 Low density 212 0x00008000 Fat containing 214 0x00010000 Cent lucent 215 0x00020000 Wall Septated internal wall 25 0x00080000 Irregular internal wall 24 0x00100000 Smooth internal wall 23 0x00200000 Thickened wall 199 0x00400000 Calcification (generic calcs) 701 0x00000001 Type Amorphous 702 0x00000002 Branching 703 0x00000004 Coarse 704 0x00000008 Dystrophic 705 0x00000010 Eggshell 706 0x00000020 Fine 707 0x00000040 Heterogeneous 708 0x00000100 Indistinct 709 0x00000200 Large rodlike 710 0x00000400 Layering 711 0x00000800 Linear 712 0x00001000 Lucent-centered 713 0x00002000 Milk of calcium 714 0x00004000 Pleomorphic 715 0x00008000 Punctate 716 0x00010000 Rim 717 0x00020000 Round 718 0x00040000 Skin 719 0x00080000 Spherical 720 0x00100000 Suture 721 0x00200000 Vascular 722 0x00400000 Calcification Clustered 751 0x00800000 Distribution Diffuse 752 0x01000000 Grouped 753 0x02000000 Linear 754 0x04000000 Regional 755 0x08000000 Scattered 756 0x10000000 Segmental 757 0x20000000 Foreign body, Hematoma 478 0x00000001 Scar, or other Nipple retract 477 0x00000002 (typically ignore) Post surgical scar 479 0x00000004 Seroma 469 0x00000008 Skin involvement 252 0x00000010 Skin lesion 473 0x00000020 Skin retraction 251 0x00000040 Skin thicken 250 0x00000080 Trab thicken 470 0x00000100 Changes from Incr in size 77 0x00000200 prior exam Decr in size 78 0x00000400 Incr in calcs 483 0x00002000 Decr in calcs 484 0x00004000 Incr in number (mass) 481 0x00008000 Decr in number (mass) 482 0x00010000 Less prom. 293 0x00020000 More prom. 294 0x00040000

Detailing window 400 displays information that can be stored as BI-RADS compatible data points, or another suitable lexicon. Optionally the ROI data can be generated by a CAD software package used to pre-evaluate and categorize the ROI in the MIS. Detailing window 400 also provides a radiologist with an interface to adjust, re-characterize, correct, or remove the ROI data based on their professional assessment of the ROI depicted in the patient's images if they radiologist disagrees with the CAD generated results. All of this information can be stored in a database configured to correlate all of a patent's ROI data and images.

The features provided by the system can also be combined with any one of several available computer aided diagnostic (CAD) products to validate, improve, and allow simplified testing of future CAD algorithms. A CAD product can be evaluated by using the electronically compiled descriptions of any abnormalities shown in a collection of ROI images to compare the CAD software algorithms against the real world pathology or biopsy results that were actually performed on the ROIs depicted in the image database.

Once the reliable performance of a CAD algorithm is established it may be used to further assist or confirm radiologist assessments of mammography images from new patients, or to alert the medical staff or radiologists when new or previously unclassified abnormalities are detected. Additionally, the integration of a CAD algorithm and the lexicon abnormality descriptors to generate ROI entries, such as those depicted in FIG. 6 b, can pre-select the ROI classifications for each abnormality detected by a CAD product. This combination is especially advantageous as it reduces the number of radiologist provided entries to only corrections to the CAD interpretation of an ROI or any ROI that were not categorized initially by the CAD product. While a handful of mouse clicks or keyboard entries, or similar gestures, may seem trivial, the combined time savings over the high volume of patient images that must be reviewed can yield a substantial savings in time, cost and comfort.

In the example embodiment discussed above, the display of the statistical results in profiler button 410 is automatically updated every time the radiologist enters or changes a data point. In another embodiment, the statistical results display window or profiler button 410 is hidden, or the update suppressed, until the entry of all of the patient's data is complete. This alternative embodiment may be useful as a training tool for educating new radiologists by preventing them from being influenced by the statistical updates as they perform their entry of the data points for a patient.

As shown in FIG. 7, when the user activates, or clicks on, the profiler button 410 of FIG. 6 b, a window of matching statistical information 500 is displayed. This window of matching statistical information 500 includes the individual quantity 502 and the percentages 504 for malignant and benign outcomes in a sorted itemized list with both local and national data based on the matching selected abnormality features. Additionally, window 500 also includes the various pathology findings 506, as well as the code for that finding 508, contained in the database.

The example embodiment provides a “show exams” button 510 that allows a radiologist to retrieve the examinations for an individually selected pathology type 512. FIG. 8 depicts an examination list window 550 for the selected pathological type 512. The matching exams displayed in FIG. 8 are only those database records from the local facility database. Any records retrieved from a non-local database would not contain any patient identifying information. The embodiment of the MIS depicted here further provides the radiologist with the opportunity to select a record 560 of individual patient with the same diagnosis 512 for further review. The selection of the “View patient priors” button 570 directs the system to open a window containing the selected patient's examination record and “Send Images to Viewstation” button 572 that can be selected to send images to display workstation 100 or image monitors 112 and 114 that allows the radiologist to view multiple matching imaging features and pathological outcomes in similar imaging modalities.

FIG. 9 depicts an exemplary prior exam window 600 displaying the images for an individual patient's exam. Prior exam window 600 includes existing or historical exam images for the selected patient for referencing process of care. By selecting an individual exam report 602 and then one of the “View Full” 604, “Preview” 606, “Print” 608, or “Send to Viewstation” 610, the radiologist can examine the selected exam report 602 and optionally compare the images contained in that record to the current patient's images. Additionally, the system allows the radiologist to export a variety of bulk data, such as to a CD or other location with the “Create CD” button 612 option. The bulk data may include all of the images related to a single patient or a collection of categorized abnormality images that match a set of selected abnormality attributes or some other data subset.

FIG. 10 depicts a patient report 700 summarizing the details of the CAD or radiologist findings from the examination and analysis of the patient's images. The report 700 can contain a clipped portion of the medical image or a thumbnail picture summarizing the ROI, as well as a multi-perspective wireframe guide that maps the location of the ROI onto the outline of the patient's anatomy.

FIG. 11 through FIG. 14 depict an exemplary embodiment of a standalone or web-based interface 800 to an embodiment of the profiler system. The web-based interface 800 can be accessed with any of the commonly available web browsers such as Microsoft Internet Explorer or Mozilla Firefox. As appreciated by those skilled in the art, a web-based interface may be hosted on a server connected to the Internet for use by a variety of geographically separated individuals or locally where access is limited to a particular facility's local network.

FIG. 11 depicts a web-based interface 800 providing a mechanism to select various characteristics regarding abnormality information contained in a database. Four modalities are presented, Mammogram-Mass 802, Mammogram-Calcification 804, MRI 806 and Ultrasound (US) 808. Depending on the modality selected, additional characteristics related to the selected modality are displayed to provide further details of the abnormality information request. The example depicted in FIG. 11 indicates a request for abnormality information contained in the database where the abnormality is categorized as a Mammogram-Mass 802, has an irregular shape 810, a speculated margin 812, and a high density 814. Mammogram-Mass 802 can also have associated calcification types 818.

As depicted in FIG. 12, the Mammogram-Calcification 804 modality is selected as the primary abnormality, and the Mass column containing the Shape 810, Margin 812, Density 814, and Orientation 816 categories, shown in FIG. 11, are removed from the interface 800. Interface 800 can include a results summary display area 820 and a matching pathology display area 840. The results summary display area 820, in a manner similar to the profiler button 410 of FIG. 6 a, displays a count of matching abnormalities and their pathological outcome that were found in the database, as well as the percentages of the biopsied abnormalities that we either malignant or benign.

The matching pathology display area 840 can include a list of findings that can detail the percentages of a pathology diagnosis for abnormalities that were malignant or benign. The display area 840 example includes the result 842 as either malignant or benign, the number of entries 844 in the national database, the percentage 846 that each pathology represents of either the malignant or benign diagnosis, a pathology code 848 and a summary of the finding 850. Both the results summary display area 820 and the matching pathology display area 840 are updated whenever a new abnormality categorization is selected.

FIG. 13 depicts an example embodiment of interface 800 displaying categories that are related to the MRI 806 modality. As shown in the “Percent of” column 852 of the matching pathology display area 840, the percentages of the abnormality diagnosis are calculated as the number of relevant diagnosis from the total number of just the malignant or just the benign results. As shown, the percentages of malignant diagnosis equal 100% and the benign diagnosis equal 100%.

FIG. 14 depicts an example embodiment of interface 800 displaying categories that are related to the ultrasound 808 modality. The ultrasound 808 modality includes fields for “Boundary,” “Hilum,” Echo,” and “Internal Echo” in column 860 that are specific to ultrasound imaging techniques. It is contemplated that other fields, columns, or modalities can be added or presented as needed to accommodate the preferences of the user or to incorporate other new or existing diagnostic technologies.

FIG. 15 depicts an embodiment of a ROI Gallery 900 containing selected image clippings 910 that have been associated with the ROI depicted by the craniocaudal mark 252. The activation of the “Roi Gallery” button 290, shown in FIG. 3, causes the ROI Gallery 900 to be presented to the user. The image clippings 910 can be selected from any region of a medical image available to the radiologist on the MIS. A low magnification image 912 can be useful to identify a large area of tissue. Alternatively, a smaller, higher magnification image 914 can provide the radiologist with greater detail.

The association of image clippings 910 can allow the radiologist to associate a variety of images with the set of categories, such as those associated with the ROI of FIG. 3. By correlating a subset of a full resolution image the radiologist is able to focus on the specific area that is described by the characteristics. This correlation of ROI characteristics with any of a variety of radiologist selected image clippings 910 can then be used in during future examinations to quickly focus in on individual areas that may need review. One example would be clipping a view of an abnormality that the radiologist recommended be reviewed after six or twelve months for any changes in size or appearance.

Additionally, the system provides for the clipping of various modalities of images. In addition to the mammogram images as shown in the ROI Gallery 900, additional images such as ultrasound or MRI captures can also be included in the gallery. One embodiment of this system can employ the storage of individual image clippings 910 in a compressed image format, such as the JPEG image format established by the Joint Photographic Experts Group, or another appropriate standard. The use of a compressed image format provides an acceptable resolution for a thumbnail image for an initial investigation, while requiring less storage space than a high-resolution image format, such as the DICOM format. The system also provides a link from the compressed image clippings 910 to the full-sized high-resolution image for the situations, such as making a diagnostic assessment, that require a radiologist to view the high-resolution image.

In one embodiment of the system, a database of thumbnail or clipped images can provide a source of investigational data that may assist a radiologist in categorizing an abnormality that he or she is unfamiliar with, or for use as a training tool. The association of the ROI categorizations with the clipped images also provides an efficient mechanism to search for individual image clippings 910 of a particular type of abnormality or to provide a convenient link to pathology reports or patient correspondence. Non-image based information such as patient correspondence or reports can be stored in the ROI Gallery 500 either in their native format or in an image format, such as JPEG, TIFF, GIF, or another appropriate standard, derived from a screen-capture of the report or document.

FIG. 16 a is another depiction of ROI Gallery 900. Image clipping 910, as well as other images, can be attached or associated directly to an abnormality, such as ROI, depicted by the craniocaudal mark 252. FIG. 16 b depicts of ROI Gallery 900 with a single highlighted image clipping 910 as indicated by highlight-bar 920. Various exemplary tools are shown in ROI Gallery 900 that provide for the manipulation of individual image clippings. When an image is associated to an abnormality, the title bar 920 changes color, indicating a direct association. Tapping the “+” 924 provides a mechanism to attach image to abnormality 910. Tapping “−” 926 disassociates image clipping 910 if attached to an ROI. A double-click on image clipping 910 or tapping on magnification button 928 brings up an individual ROI viewer 950 to allow a large view along with access to other imaging tools.

Within the title bar the description of the view is displayed from the image it was obtained from, for example RCC (RightCranioCaudal) image. In an embodiment, if the image was processed through a CAD tool, the feature descriptors, such as CAD-generated ROI outlines provided by that tool, are displayed. In another embodiment, feature descriptors can be superimposed as an overlay on top of the image. Alternatively, a hovering tool bar tool, for example when a user leaves the mouse cursor over an image, provides a small message describing the area. Additionally, in order to reduce right/left errors when associating images to an ROI, the imaging gallery does not allow right ROI to be associated to left breast abnormality, and a left ROI is not allowed to be associated with a right breast image or abnormality.

As depicted, a user can delete 922 the image clipping 910, or open the image clipping 910 in an individual ROI viewer upon the selection of magnification button 928.

FIG. 17 depicts an example embodiment of a ROI viewer 950 depicting an individual image 952. The ROI viewer 950 provides additional image manipulation tools, including an “invert” selector 954 that replaces the black pixels for white and the white pixels for black. The ROI viewer 950 also provides a “3D” button 956 that can support the activation of a separate 3D-modeling software package, one example of which is available from Clario, that enables the radiologist to view and rotate a composite three-dimensional image of the associated ROI. The radiologist may return to the ROI Gallery 900 by selecting either the “Exit” button 958 or the “Close Window” icon 960.

FIG. 18 is an example of a patient work-list form 1000 for use with embodiments of this invention. The work-list form 1000 allows the system to coordinate the retrieval of any high-resolution images in order to effectively utilize network bandwidth and system storage capacity. FIG. 19 is an example of a prior examinations form 1100 for use with embodiments of this invention. The prior examination form 1100 provides a radiologist with convenient access to a patient's prior medical image for review or comparison with a more current set of images.

As shown by the preceding examples, the invention provides an integrated system and methods for the categorization, storage, retrieval, and correlation of a wide variety of patient data, diagnostic images from multiple imaging sources, test results, statistics and correspondence. The integration of a ROI profiler, a statistical analysis tool, and the gallery of clipped images, together with native high-resolution medical images provides radiologists and other medical professionals with a customizable tool that provides greater efficiencies while also improving the accuracy of patient diagnostic screenings.

The foregoing descriptions present numerous specific details that provide a thorough understanding of various embodiments of the invention. It will be apparent to one skilled in the art that various embodiments, having been disclosed herein, may be practiced without some or all of these specific details. In other instances, known components have not been described in detail in order to avoid unnecessarily obscuring the present invention. It is to be understood that even though numerous characteristics and advantages of various embodiments are set forth in the foregoing description, together with details of the structure and function of various embodiments, this disclosure is illustrative only. Other embodiments may be constructed that nevertheless employ the principles and spirit of the present invention. Accordingly, this application is intended to cover any adaptations or variations of the invention. It is manifestly intended that this invention be limited only by the following claims and equivalents thereof.

For purposes of interpreting the claims for the present invention, it is expressly intended that the provisions of Section 112, sixth paragraph of 35 U.S.C. are not to be invoked with respect to a given claim unless the specific terms “means for” or “step for” are recited in that claim.

Any incorporation by reference of documents above is limited such that no subject matter is incorporated that is contrary to the explicit disclosure herein. Any incorporation by reference of non-priority documents above is further limited such that no claims included in the documents are incorporated by reference herein and any definitions provided in the documents are not incorporated by reference herein unless expressly included herein. 

1-20. (canceled)
 21. A mammography information system comprising: at least one electronic display; a graphical user interface presented on the at least one electronic display and configured to present data related to a patient, the graphical user interface comprising an image gallery configured to display thumbnail representations of a plurality of images that form a portion of the data and information, each the plurality of images having an imaging modality of at least one at radiological images, X-ray images, computed tomography images, magnetic resonance images, ultrasound images, pathology images, tomosynthesis images, and document images; a thumbnail database operable to store the thumbnail representations of the plurality of images; a first networked database operable to store a plurality of medical-facility-categorized images including categorizations from a medical facility for comparison against the plurality of images; and a second networked database operable to store a plurality of multiple-medical-facility-categorized images including categorizations from a least two medical facilities for comparison against the plurality of images.
 22. The system of claim 21, wherein the document images comprise at least a portion of at least one of a report, a letter, a lab result, and a text document.
 23. The system of claim 21, further comprising an anatomical diagram presented on the graphical user interface and on which at least one region of interest corresponding to a region of interest in at least one of the plurality of images can be indicated by a mark.
 24. The system of claim 21, wherein the mark on the anatomical diagram is linked to the at least one of the plurality of images.
 25. The system of claim 21, wherein the graphical user interface is configured to present an adjacent display of statistical information from a comparison of one of the plurality of images with the categorizations of the first networked database and the second networked database.
 26. The system of claim 25, wherein the statistical information comprises a number of biopsies performed that were diagnosed as malignancies, a number of biopsies performed that were diagnosed as benign, and a total number of matching abnormalities.
 27. The system of claim 21, wherein each of the plurality of medical-facility-categorized images and each of the plurality of multiple-medical-facility-categorized images is cataloged in the first or second networked databases according to a characteristic of the image.
 28. A multiple modality tissue image profiler comprising: a database of existing pathological findings for a plurality of tissue abnormalities, each tissue abnormality located in a region of interest of one of a plurality of tissue images; a graphical user interface configured to present a plurality of possible characteristics according to which a tissue abnormality can be characterized; and a processor configured to identify existing categorizations in the database that match selected ones of the plurality of possible characteristics and to retrieve at least one image having at least one of the selected ones of the plurality of possible characteristics based on a comparison with the existing categorizations and to present the at least one image depicting the characterized tissue abnormality in the graphical user interface, wherein each of the plurality of images has an imaging modality of at least one of radiological, X-ray, computed tomography, magnetic resonance, ultrasound, pathology, and tomosynthesis.
 29. The image profile of claim 28, wherein the existing categorizations in the database are identified using a computer aided diagnosis (CAD) categorization.
 30. The image profile of claim 28, wherein the database comprises existing pathological findings for a plurality of tissue abnormalities for a local medical facility.
 31. The image profile of claim 30, further comprising a second database of existing pathological findings for a plurality of tissue abnormalities, wherein the second database comprises existing pathological findings for a plurality of medical facilities.
 32. The image profiler of claim 31, wherein the processor is further configured to identify existing categorizations in the second database that match selected ones of the plurality of possible characteristics and to retrieve at least one image of the second database having at least one of the selected ones of the plurality of possible characteristics based on a comparison with the existing categorizations and to present the at least one image of the second database depicting the characterized tissue abnormality in the graphical user interface.
 33. The image profiler of claim 28, wherein the database is configured to store the existing pathological findings according to a hexadecimal value assigned to at least one of the selected ones of the plurality of possible characteristics.
 34. The image profiler of claim 33, wherein the processor is configured to identify the existing categorizations in the database that match selected ones of the plurality of possible characteristics based on a bitwise operation of the hexadecimal value.
 35. The image profiler of claim 34, wherein the processor is further configured to identify the existing categorizations in the database that match selected ones of the plurality of possible characteristics based on an index value to the hexadecimal values. 